Distribution system, reception apparatus, and methods for transitioning to new services

ABSTRACT

A distribution system and reception apparatus, and methods thereof, are provided for broadcasting and receiving a plurality of non-backwards-compatible services. The broadcasting method includes receiving, by a first service provider, a plurality of first services, which include a first service from each of the first and second service providers. The first service provider generates a first broadcast multiplex, including the plurality of first services, and broadcasts the first broadcast multiplex on a first broadcast channel allocated to the first service provider. A second service provider receives a plurality of second services, which include a second service from each of the first and second service providers. The second service provider generates a second broadcast multiplex, including the plurality of second services, and broadcasts the second broadcast multiplex on a second broadcast channel allocated to the second service provider.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.14/512,761, filed Oct. 13, 2014, which is a divisional of U.S.application Ser. No. 13/930,814, filed Jun. 28, 2013, now U.S. Pat. No.9,137,566, the entire contents of both of which are incorporated hereinby reference.

BACKGROUND OF THE INVENTION Field of the Invention

Embodiments described herein relate generally to transitioning to newservices.

Background

Modern televisions and set top boxes are capable of receiving broadcasttelevision services. However, due to limitations in wireless spectrumavailability, broadcast television service providers may not havesufficient spectrum to provide new services that are not backwardscompatible while maintaining the availability of existing (or legacy)services.

SUMMARY OF THE INVENTION

Embodiments of the present disclosure relate to addressing the problemof transitioning to new services when wireless spectrum is limited.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the invention and many of the attendantadvantages thereof will be readily obtained as the same becomes betterunderstood by reference to the following detailed description whenconsidered in connection with the accompanying drawings, wherein:

FIG. 1 illustrates an exemplary broadcast system;

FIG. 2 illustrates an exemplary transition methodology;

FIG. 3A illustrates an example of channel re-use;

FIGS. 3B-3D illustrate examples of broadcast spectrum usage;

FIG. 4 illustrates an example of the broadcast spectrum;

FIG. 5 illustrates an example of a distribution system;

FIG. 6 illustrates an example of a signal generator;

FIG. 7 illustrates an exemplary protocol stack;

FIG. 8 is a block diagram of an exemplary reception apparatus;

FIG. 9 illustrates a flow diagram of an exemplary reception method; and

FIG. 10 is an exemplary computer.

DETAILED DESCRIPTION

While the present disclosure is susceptible of embodiment in manydifferent forms, there is shown in the drawings and will herein bedescribed in detail specific embodiments, with the understanding thatthe present disclosure of such embodiments is to be considered as anexample of the principles and not intended to limit the presentdisclosure to the specific embodiments shown and described. In thedescription below, like reference numerals are used to describe thesame, similar or corresponding parts in the several views of thedrawings.

The terms “a” or “an”, as used herein, are defined as one or more thanone. The term “plurality”, as used herein, is defined as two or morethan two. The term “another”, as used herein, is defined as at least asecond or more. The terms “including” and/or “having”, as used herein,are defined as comprising (i.e., open language). The term “coupled”, asused herein, is defined as connected, although not necessarily directly,and not necessarily mechanically. The term “program” or “computerprogram” or similar terms, as used herein, is defined as a sequence ofinstructions designed for execution on a computer system. A “program”,or “computer program”, may include a subroutine, a program module, ascript, a function, a procedure, an object method, an objectimplementation, in an executable application, an applet, a servlet, asource code, an object code, a shared library/dynamic load libraryand/or other sequence of instructions designed for execution on acomputer system.

The term “program”, as used herein, may also be used in a second context(the above definition being for the first context). In the secondcontext, the term is used in the sense of a “television program”. Inthis context, the term is used to mean any coherent sequence ofaudio/video content such as those which would be interpreted as andreported in an electronic program guide (EPG) as a single televisionprogram, without regard for whether the content is a movie, sportingevent, segment of a multi-part series, news broadcast, etc. The term mayalso be interpreted to encompass commercial spots and other program-likecontent which may not be reported as a program in an EPG.

Reference throughout this document to “one embodiment”, “certainembodiments”, “an embodiment”, “an implementation”, “an example” orsimilar terms means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment of the present disclosure. Thus, theappearances of such phrases or in various places throughout thisspecification are not necessarily all referring to the same embodiment.Furthermore, the particular features, structures, or characteristics maybe combined in any suitable manner in one or more embodiments withoutlimitation.

The term “or” as used herein is to be interpreted as an inclusive ormeaning any one or any combination. Therefore, “A, B or C” means “any ofthe following: A; B; C; A and B; A and C; B and C; A, B and C”. Anexception to this definition will occur only when a combination ofelements, functions, steps or acts are in some way inherently mutuallyexclusive.

Embodiments of the disclosure are directed to transitioning fromexisting services to new services. Examples include transitions to nextgeneration broadcast television (NGBT) services, next generation radioservices, new Mobile Network Operator (MNO) services, etc.

Although the present disclosure is described using NGBT services as aprimary example, it should be noted that the same principles alsoapplies to other new services, such as those listed above. Moreover,while embodiments of the disclosure are directed to providingtransitioning in wireless environments, similar principles can beapplied to wired environments.

Certain embodiments of the disclosure are directed to transitioning toNGBT services that are not compatible with existing terrestrialbroadcast services. In the case of a non-backwards-compatible system,the new NGBT services provide improvements in performance,functionality, and/or efficiency to facilitate its implementation. Thenew NGBT services provide new services such as mobile television,ultra-high-definition television (UHDTV) services, new audio and videocodecs, more robust and/or efficient transmission methods, moreoperational modes, broadcaster control parameters, consumer controlparameters, interactivity, etc.

For example, one NGBT service (i.e., the proposed Advanced TelevisionSystems Committee (ATSC) 3.0) is planned to be a non-backwardscompatible service to the existing 8-level vestigial sideband (8-VSB)modulation digital television broadcast service. The lack of backwardscompatibility is due to the fact that other efficient technologies arenow available that use wireless spectrum more efficiently, for exampleusing orthogonal frequency-division multiplexing (OFDM)-low-densityparity-check (LDPC) based technology. OFDM-LDPC based technology hasalready been adopted in other parts of the world and is likely to beadopted in a NGBT service.

With this new technology comes a new problem of how to transition from8-VSB modulation to a non-backwards compatible modulation scheme (e.g.,OFDM-based modulation). The present disclosure discusses an exemplarytransition plan according to certain embodiments that offers one or acombination of avenues for broadcasters to take, depending on factorssuch as Federal Communications Commission (FCC) action (or non-action),broadcaster business deals, general motivation to use new services, etc.

Each avenue could be taken in its entirety as a solution, or anycombination described herein could be utilized. As a result, thetransition can be a balanced effort between broadcasters and the FCC.Markets could transition slow or fast depending on how effective eachavenue of transition is applied. Further, the transition could beserially applied or in parallel where the FCC allocated extra spectrumand broadcaster deals are made. The order in which each avenue isapplied can also be varied.

A transition plan is needed to get to the new NGBT service. An exemplarytransition plan includes one or a combination of the following avenues:(1) have broadcasters double up their legacy service on one channelwhile supporting the NGBT service on another; (2) if difficulties arise,have the FCC allocate space in their re-pack of “voluntary auctions” fora transition area; and (3) if allocating space by the FCC is difficult,use a border channel (e.g., a broadcast channel that is adjacent to aMNO channel) such as channel 52 or 32 as a hard transition channel.

In one embodiment, the most desirable way to transition to the NGBTservice is to not involve the FCC moving/reallocating frequency for thenew transition. To accomplish this, broadcast channels are re-used withor without more efficient coding.

For example, existing services may be coded using MPEG-4, which isdouble the efficiency of MPEG-2, and is used in broadcasting in otherparts of the world. Even ATSC Mobile DTV (ATSC standard A/153, which isincorporated herein by reference in its entirety) uses it. Moreover, theencoder is often in the same piece of equipment as the MPEG-2 encoderfor broadcasters, so it is a simple cable re-locating exercise to putinto practice (e.g., instead of connect to input A, connect to input B).As for receivers, MPEG-4 or Advanced Video Coding (AVC) decoders are inmass supply, or already integrated into televisions today to decodeMobile DTV, digital video broadcasting (DVB) based signals, Internetstreaming signals, etc.

So, MPEG-4 encoding is currently available to broadcasters and MPEG-4decoding is already available in receivers. To hook up a high-definitiontelevision (HDTV) service to MPEG-4 coding would not alienate manyreceivers and therefore could be used to combine 2 broadcasters' HDVTcontent into 1 broadcast channel.

Alternatively, to ensure compatibility with legacy devices, existingservices are encoded using MPEG-2. However, MPEG-2 may not allowmultiple high-definition services to be carried on a single broadcastchannel. Accordingly, in certain embodiments, the existing services aretransmitted in MPEG-2 with a lower bit rate (e.g., in the case ofstandard-definition television), as further described below.

The broadcasters would need to find a business solution and they bothwould want to transition to NGBT services. Further, the agreements couldbe strongly recommended by industry. But the fact that the FCC wouldhave to do nothing is advantageous as a transition could thereforehappen more quickly. One broadcast channel could be dedicated to legacyHDTV services and the other broadcast channel could use the new NGBTservices.

If business agreements could not be made in a market, another option isthat part of the transition could start to involve the FCC, for exampleat the time the FCC re-packs the wireless spectrum they obtain from the“voluntary auctions” slated to take place in the next few years. Trialperiods where a transition channel is used for each set of broadcasterscan be utilized.

The FCC is currently executing its National Broadband Plan to extendInternet services to the entire public. This involves giving spectrum toMNOs. The spectrum at issue includes the 700 MHz band channelspreviously occupied by television broadcasters. Currently the FCC isusing “voluntary auctions” to gain even more spectrum for the MNOs,referred to as the 600 MHz band plan. Thoughts are that broadcastchannels are desired for re-allocation. The auctions are expected togive a little bit of spectrum back and the FCC is expected to go throughanother round of channel re-packing. According to certain embodiments ofthe present disclosure, at least one block of spectrum is allocated bythe FCC for NGBT transition services. The transition channel could beused on a broadcaster by broadcaster basis as a market transitions. Inone embodiment, the transition channel is allocated with enough spectrumto support at least one service (e.g., fixed or mobile) for broadcastersto experiment with. Further, in one embodiment, the amount of transitionspectrum is enough to support at least 4 major networks in a market(e.g., a 6 MHz channel).

As discussed above, in one embodiment, the transitions are not just forNGBT services (e.g., the proposed ATSC 3.0, a future ATSC 4.0), but anytransition. For example, in order to make this option more appealing,the transition may be opened to other entities other than terrestrialtelevision broadcasters such as radio broadcast providers and MNOs. Thisway a market can start to transition to a new service with one channel.This channel could be used by broadcasters in turn.

As noted above, in one embodiment it would be advantageous if enoughspectrum is available to transition at least the top 4 networks at thesame time. For example, for the proposed ATSC 3.0, the channel couldonly be 6 MHz for 4 networks depending on the type of service desired(e.g., mobile services).

Depending on how much spectrum is obtained from the “voluntaryauctions,” more frequency may be needed or more broadcasters may want totransition services. Thus, in one embodiment, border channels areallocated for transition services.

For example, Verizon wants to sell its lower 700 MHz A and B blocklicenses (e.g., channel 52) due to interference from broadcasters.Verizon has stated that the lower-band spectrum is not suitable forlong-term evolution (LTE) capacity requirements due to the fact thatbroadcasters on channel 51 adjacent to the A block spectrum splatteringenergy into their channel.

Accordingly, if Verizon is complaining of energy spill-over frombroadcasters, use it as a transition space. The FCC could re-purposethat channel as a transition channel. It is already on the edge of the700 MHz band and since the MNOs are complaining of powerfulbroadcasters, the FCC can allocate that channel back to broadcasters, ata lower power in one embodiment, for the transition to NGBT servicesusing a more efficient transmission scheme, for example for the upcomingbit demand in video. Further, as wireless spectrum is re-packed and/orreallocated by the FCC, other border channels may result that would besuitable for transition services (e.g., channel 32).

In certain embodiments, the transition broadcast channel is within arange of 470 MHz to 578 MHz based on possible reallocation of broadcastspectrum to wireless broadband services. As described above, in oneembodiment, the transition broadcast channel is placed adjacent to achannel used for another purpose (e.g., wireless broadband), or betweena television broadcast channel and the channel used for another purpose,to reduce interference effects by, for example, broadcasting the NGBTservices at a power lower than existing broadcast services. For example,the transition broadcast channel may be a 6 MHz channel from 578 to 584MHz (i.e., channel 32) or 698 to 704 MHz (i.e., channel 52).

In other embodiments, the transition broadcast channel is allocatedwithin the very high frequency (VHF) band in a range of 54-88 MHz and/or174-216 MHz. The VHF band is used for the transition broadcast channelto, for example, allow the broadcast providers to perform the hardswitch in the UHF band, which allows for better signal penetration.

FIG. 1 illustrates an exemplary terrestrial broadcast system 2 forproviding a plurality of first (e.g., NGBT) and second (e.g., existingor legacy broadcast) services. The terrestrial broadcast system 2includes a legacy broadcast provider 10; partner broadcast providers 15a, 15 b (also referred to as service providers); a reception apparatus20; a server 40; and a transition broadcast provider 25. Although FIG. 1illustrates one legacy broadcast provider 10; two partner broadcastproviders 15 a, 15 b; one reception apparatus 20; one server 40; and onetransition broadcast provider 25, it should be understood that anynumber of each may be included in the broadcast system 2.

The legacy broadcast provider 10 broadcasts a legacy service to thereception apparatus 20. The legacy service is broadcast according to anexisting digital television standard (e.g., ATSC standard A/53, which isincorporated herein by reference in its entirety) in use before the NGBTservice. The legacy broadcast provider 10 is allocated a broadcastchannel (also referred to as an RF channel) on which the legacy serviceis broadcast. However, the legacy broadcast provider 10 is unable tobroadcast any NGBT services, which are not backwards compatible with theexisting service due to lack of wireless spectrum.

To allow a broadcast provider to provide legacy services and NGBTservices that are not backwards compatible with the legacy services whenwireless spectrum is limited, in certain embodiments, the broadcastproviders enter into an agreement (e.g., a contractual agreement) tobroadcast legacy services on one broadcaster's broadcast channel and tobroadcast NGBT services on the other broadcaster's broadcast channel.

Partner broadcast providers 15 a, 15 b are examples of broadcastproviders that have entered into such an agreement. As illustrated inFIG. 1, the partner broadcast provider 15 a broadcasts a plurality ofNGBT services (e.g., a plurality of first services) from a plurality ofdifferent broadcast providers 15 a, 15 b on a first broadcast channel.The partner broadcast partner 15 b broadcast a plurality of legacyservices (e.g., a plurality of second services) on a second broadcastchannel. Each of the broadcast providers 10, 15 a, 15 b broadcastrespective services using a broadcast tower via a studio to transmitterlink (STL).

In one embodiment, the legacy and NGBT services provided by the legacybroadcast provider 10 and partner broadcast providers 15 a, 15 b,respectively, are television broadcast services that include one or moretelevision content, without regard to whether the content is a movie,sporting event, segment of a multi-part series, news broadcast, etc.Further, the legacy and NGBT services may also include advertisements,infomercials, and other program-like content which may not be reportedas a program in an EPG.

The plurality of NGBT services are broadcast using a first transmissionscheme such as a transmission scheme based on orthogonalfrequency-division multiplexing (OFDM) and the plurality of legacyservices are broadcast using a second transmission scheme such as 8-VSB.However, any other combination of incompatible transmission schemes(i.e., not capable of simultaneously broadcast on the same broadcastchannel) may be used to transmit the plurality of NGBT and legacyservices. In one embodiment, the partner broadcast providers 15 a, 15 bbroadcast digital television signals in accordance with standards set,for example, by the Advanced Television Systems Committee (ATSC) such asATSC standard A/53.

Further, although the partner broadcast providers 15 a, 15 b and thelegacy broadcast provider 10 are illustrated as each being associatedwith a separate broadcast tower, contractual agreements may be madebetween any two or more of the partner broadcast providers 15 a, 15 band the legacy broadcast provider 10. For example, partner broadcastprovider 15 a may enter into a contractual agreement with partnerbroadcast provider 15 b such that both partner broadcast providers 15 a,15 b use the same broadcast tower to provide the plurality of NGBT andlegacy services.

In one embodiment, the legacy broadcast provider 10 and partnerbroadcast providers 15 a, 15 b provide the plurality of NGBT and legacyservices via terrestrial broadcasts. In the case of audio/video content,the content is compressed and broadcast using different transmissionschemes, as discussed above.

For example, the audio/video content of the plurality of NGBT and legacyservices is divided into a video elementary stream (ES) and an audio EScorresponding to the video and audio portions of the content. The videoES and audio ES are multiplexed with other data to form a broadcastmultiplex, such as an MPEG-2 Transport Stream (TS), MPEG Media Transport(MMT) or similar technology in the case of the broadcast by the legacybroadcast provider 10 and partner broadcast provider 15 b. Further, inone embodiment, the first broadcast channel carries a transport (e.g.,an MMT) or IP packets, which is different than that broadcast by thepartner broadcast provider 15 b.

The reception apparatus 20 is configured to receive the plurality oflegacy services broadcast by the legacy broadcast provider 10 andpartner broadcast provider 15 b. Alternatively, or additionally, thereception apparatus 20 is configured to receive the plurality of NGBTservices broadcast by the partner broadcast provider 15 a or newservices from other sources. The plurality of legacy services is alsoprovided to consumer devices that are not configured to receive theplurality of NGBT services (e.g., a television with a ATSC A/53receiver).

The reception apparatus 20 is a home video processor such as a personalcomputer, television receiver or DVD recorder, or an informationprocessor such as a Personal Digital Assistant (PDA), mobile phone,tablet, home or portable music player, or home or portable gamingmachine. Further, the reception apparatus 20 may be a standalone deviceor incorporated, for example, in a television set or other consumerelectronics device.

The reception apparatus 20 is configured to connect to the Internet 30via a wireless or fixed connection. For example, when the receptionapparatus 20 is a mobile device, the reception apparatus 20 connects tothe Internet 30 via a mobile data connection or Wi-Fi connection. Whenthe reception apparatus 20 is a fixed device, the reception apparatus 20connects via an Ethernet connection, wireless connection, mobile dataconnection, etc.

In one embodiment, the reception apparatus 20 connects to the Internet30 to receive or send information based on one of the plurality of NGBTservices broadcast by the partner broadcast provider 15 a. For example,the reception apparatus 20 may make a purchase for advertised goods,contents, or services via the Internet 30, request additionalinformation related to the one of the plurality of NGBT services,interface to a social network website based on instructions accompanyingthe one of the plurality of NGBT services, etc. The reception apparatus20, in one embodiment, receives the information associated with the oneof the plurality of NGBT services from at least one server 40. In otherembodiments, the server 40 may be provided by the partner broadcastprovider 15 a or each separate partner broadcast provider 15 a, 15 b mayprovide its own server 40.

The transition broadcast provider 25 is configured to broadcast NGBTservices on a transition broadcast channel, when available. In oneembodiment, the transition broadcast provider 25 assists in broadcastingNGBT services when certain broadcast providers cannot reach an agreementwith each other. In another embodiment, the transition broadcastprovider 25 assists in broadcasting NGBT services when entering into anagreement with another broadcaster is not feasible, such as in the casethat no other broadcaster is prepared to transition to NGBT services,there are not enough broadcasters to double up services, etc.

FIG. 2 illustrates an exemplary transition plan for transitioning to aNGBT service that is not backwards compatible with one or more existingterrestrial broadcast services. In step S202, two or more broadcastproviders enter into an agreement to broadcast each other's legacy andNGBT services. For example, the partner broadcast provider 15 a (e.g., afirst service provider) enters into an contractual agreement with thepartner broadcast provider 15 b (e.g., a second service provider) suchthat partner broadcast provider 15 a broadcasts the NGBT services on afirst broadcast channel assigned to the partner broadcast provider 15 awhile the partner broadcast provider 15 b broadcasts the legacy serviceson a second broadcast channel assigned to the partner broadcast provider15 b.

In step S204, the first broadcast provider of the two or more broadcastproviders, receives a plurality of first services (e.g., NGBT services)to be broadcast on the first broadcast channel. The plurality of firstservices includes a different first service for each of the two or morebroadcast providers. For example, the partner broadcast provider 15 areceives its own first service and a first service associated with thepartner broadcast provider 15 b. In FIG. 1, the first service frompartner broadcast provider 15 b is obtained directly from partnerbroadcast provider 15 b. However, in another embodiment, the firstservices are provided directly to, or otherwise retrieved by, thepartner broadcast provider 15 a.

In step S206, the first broadcast provider generates a first broadcastmultiplex (e.g., using a first multiplexer) that includes the pluralityof first services of the two or more broadcast providers. Each of theplurality of first services is assigned a different major and minorvirtual channel number combination. In one embodiment, each of theplurality of first services is assigned the same major virtual channelnumber. In another embodiment, at least two of the plurality of firstservices are assigned different major virtual channel numbers. Forexample, the assignment of major channel numbers corresponds to themajor virtual channel number that was originally used by a respectivebroadcast provider to transmit services. In other embodiments, majorand/or minor virtual channel numbers are assigned according to otherpredetermined criteria.

In step S208, the first broadcast provider transmits the first broadcastmultiplex on a first broadcast channel that is allocated to the firstbroadcast provider. The first broadcast multiplex is transmittedaccording to a transmission scheme (e.g., OFDM) which is not backwardscompatible with, or is otherwise different from, a transmission schemeused to transmit a second broadcast multiplex by a second broadcastprovider, as described below.

In step S210, the second broadcast provider of the two or more broadcastproviders, receives a plurality of second services (e.g., legacyservices) to be broadcast on a second broadcast channel. The pluralityof second services includes a different second service for each of thetwo or more broadcast providers. For example, the partner broadcastprovider 15 b receives its own second service and a second serviceassociated with the partner broadcast provider 15 a. In FIG. 1, thesecond service from partner broadcast provider 15 a is obtained directlyfrom partner broadcast provider 15 a. However, in another embodiment,the first services are provided directly to, or otherwise retrieved by,the partner broadcast provider 15 b.

In step S212, the second broadcast provider generates a second broadcastmultiplex (e.g., using a second multiplexer) that includes the pluralityof second services of the two or more broadcast providers. Each of theplurality of second services is assigned a different major and minorvirtual channel number combination. In one embodiment, each of theplurality of first services is assigned the same major virtual channelnumber. In another embodiment, at least two of the plurality of firstservices are assigned different major virtual channel numbers. Forexample, the assignment of major channel numbers corresponds to themajor virtual channel number that was originally used by a respectivebroadcast provider to transmit services. In other embodiments, majorand/or minor virtual channel numbers are assigned according to otherpredetermined criteria.

In step S214, the second broadcast provider transmits the secondbroadcast multiplex on the second broadcast channel that is allocated tothe second broadcast provider. The second broadcast multiplex istransmitted according to a transmission scheme (e.g., 8-VSB) which isnot compatible with, or is otherwise different from, a transmissionscheme used to transmit the first broadcast multiplex by the firstbroadcast provider.

In step S216, the transition from existing services to NGBT services iscompleted and transmission of the plurality of second services ends. Atthis time each of the two or more broadcast providers broadcasts its ownNGBT service(s).

In one embodiment, the plurality of first and/or second services areapplied to broadcast channels of a 6 MHz spectrum. However, any otherspectrum size may be implemented, such as a spectrum that is a multipleof 6 MHz, based on spectrum availability. For example, broadcastproviders with adjacent broadcast channels may agree to transmit theplurality of first or second services in a combined broadcast channel.

Further, in one embodiment, the amount of spectrum allocated to theplurality of second services is greater than the first pluralityservices to account for, for example, greater efficiencies in thetransmission of the first plurality of services. For example, in thecase of three broadcasters, two broadcast channels can be combined tobroadcast legacy services while the third broadcast channel is used tobroadcast NGBT services for all three broadcasters.

FIG. 3A illustrates an example of channel re-use between two broadcastproviders to transition to NGBT services. However, it should be notedthat channel re-use can be utilized by a number of broadcast providers.Blocks 15 a′, 15 b′ represent the partner broadcast providers 15 a, 15 bprior to entering an agreement, which is represented by dashed line 310,to broadcast each other's services. Prior to entering the agreement,each of the broadcast providers 15 a′ and 15 b′ broadcasts its ownlegacy services to the reception apparatus 20. Although FIG. 3illustrates the legacy services as high-definition television (HDTV)services broadcast via 8-VSB, any other services and/or transmissionscheme may be used.

After the broadcast providers 15 a′ and 15 b′ enter into an agreement tobroadcast each other's services, the partner broadcast provider 15 abroadcasts NGBT services for both broadcast providers 15 a′, 15 b′ whilethe partner broadcast provider 15 b broadcasts legacy services (alsoreferred to as legacy services) for both broadcast providers 15 a′, 15b′.

In one embodiment, the legacy services use the same coding as originallyused by broadcast providers 15 a′, 15 b′, such as MPEG-2. A broadcastchannel can support a data rate of approximately 19.392658 Mbps However,MPEG-2 HDTV rates vary between 8-15 Mbps. Accordingly, multiple HDTVstreams may not be able to fit into a single RF channel. To address thisproblem, in one embodiment, the partner broadcast provider 15 b′broadcasts a different version of the legacy services originallybroadcast by the broadcast providers 15 a, 15 b. The versions may differby compression rate, video quality, audio quality, etc. For example, thepartner broadcast provider 15 b′ broadcasts standard definition ratherthan high definition versions of the legacy services (i.e., SDTV versusHDTV).

In another embodiment, the legacy services use a different coding thanoriginally used by the broadcast providers 15 a′, 15 b′, such as a moreefficient coding type (e.g., MPEG-4 AVC). For example, MPEG-4 coding hashalf the required bit rate than MPEG-2 and MPEG-4 HDTV rates varybetween 4-8 Mbps. Accordingly, even at the highest rate of 8 Mbps, 2HDTV services can fit within the broadcast channel with room to spare.

An advantage of using MPEG-4 AVC (also referred to as H.264) is thatmany current televisions already have AVC decoders. H.264 is perhapsbest known as being one of the codec standards for Blu-ray discs. It isalso widely used by streaming Internet sources, such as videos fromYouTube, and the iTunes Store. Web software such as Adobe Flash Playerand Microsoft Silverlight and various HDTV broadcasts over terrestrial(ATSC, Integrated Services Digital Broadcasting-Terrestrial (ISDB-T),Digital Video Broadcasting-Terrestrial (DVB-T), or Digital VideoBroadcasting—Second Generation Terrestrial (DVB-T2), cable (DVB-C) andsatellite (DVB-S and DVB-S2) also use H.264 AVC coding. So, worldwideTVs require this codec. According, MPEG-4 is expected to be supported byalmost all TV's by the time existing HDTV services transition to NGBTservices.

Further, broadcast transmitters also require the H.264 codec as it iscurrently used in Mobile DTV (A/153) and other standards. Hooking upthis codec is relatively easy as the transmitter encoder has both MPEG-2and MPEG-4 coders in the same piece of equipment. Accordingly, becausethe AVC codec are currently in use, this codec can be easily utilizedfor the transition.

Although many television sets are equipped with MPEG-4 decoders, sometelevision sets are configured such that the MPEG-4 decoders are used todecode non-terrestrial broadcast services. Accordingly, these televisionsets may need to be reprogrammed to utilize the MPEG-4 decoder for theterrestrial broadcast services. Alternatively, set top boxes may beconnected to the television sets to receive legacy services. Dependingon the feasibility of reconfiguring television sets to utilize MPEG-4,MPEG-2 may be utilized to ensure compatibility.

FIGS. 3B-3D illustrate an example of broadcast spectrum usage whentransitioning to NGBT services. In one embodiment, the broadcastchannels are consistent with the television broadcast channel allocationillustrated in FIG. 4. The broadcast channels may or may not occupy aportion of the broadcast spectrum between 578 MHz and 698 MHz based onwhether the FCC reallocates that frequency band for other uses such aswireless broadband.

FIG. 3B illustrates an example of broadcast spectrum usage for existingdigital television broadcast services according to ATSC A/53. Thebroadcast spectrum includes unused broadcast channels 310 and occupiedbroadcast channels such as broadcast channels 325 a, 335 a. The FCC isexpected to reallocate portions of the existing broadcast spectrumavailable for existing television broadcast services for other purposes,such as broadband services. After this allocation (or repack), in aworst case scenario, no unused broadcast channels would be available incrowded markets.

By re-using broadcast channels to broadcast legacy and NGBT services, atransition from the legacy to the NGBT services can still be made evenwhen unused broadcast channels are not available. When unused broadcastchannels are available, at least one broadcast channel is optionallyallocated as a transition broadcast channel 330, as illustrated in FIG.3C. The at least one transition broadcast channel 330 may be assigned bya government entity such as the FCC or determined by the individualtelevision broadcasters. An exemplary transition channel is disclosed inU.S. provisional application No. 61/733,242, which is incorporatedherein by reference in its entirety.

The at least one transition broadcast channel 330 may or may not haveenough capacity to concurrently carry a NGBT service from each of thebroadcast providers in the same market. In one embodiment, each of theat least one broadcast channel 330 has sufficient capacity to carry sixdifferent NGBT services. Depending on the embodiment, each of the sixdifferent first services are provided by a different broadcast provideror the same broadcast provider may provide two or more of the sixdifferent services. However, other numbers of services may be providedon the transition broadcast channel 330 based on bit rate requirements.

The at least one transition broadcast channel 330 allows broadcastproviders (e.g., broadcast providers 15 a′, 15 b′) to provide legacy andNGBT services, concurrently, until the broadcast providers switch theirown broadcasts to the NGBT services. In one embodiment, the broadcastproviders include the same content in both the legacy and NGBT services.In a further embodiment, the broadcast providers include higherresolution, or otherwise enhanced, content in the NGBT services.

FIG. 3C illustrates a broadcast channel 325 b used to broadcast NGBTservices from two or more different broadcast providers, and a broadcastchannel 335 b used to broadcast legacy services from the two or moredifferent broadcast providers (e.g., originally broadcast on broadcastchannels 325 a, 335 a).

FIG. 3D illustrates an example where some of the broadcast providershave switched their own broadcast channels to broadcasting the NGBTservices. For example, the broadcast channels 325 b, 335 b now broadcastNGBT services of their respective broadcast providers as illustrated bybroadcast channels 325 c, 335 c. Further, as other broadcast providerstransition to broadcasting the NGBT services, transition broadcastchannel space is freed up for use by other broadcast providers.

If necessary, transition broadcast channel access by each broadcastprovider may be prioritized based on a lottery, auction, businessagreement between the various broadcast providers, etc. For example,transition broadcast channel space may be allocated to broadcastproviders that are unable to form an agreement with another broadcastprovider to broadcast each other's services.

FIG. 5 illustrates an example of a distribution system 500 used by thepartner broadcast provider 15 a to broadcast the plurality of NGBTservices in one embodiment. The distribution system 500 includes atleast one receiver (e.g., receivers 510 a-510 f, one for each NGBTservice) to receive the plurality of NGBT services to be provided by thedistribution system 500. In other embodiments, one of the receivers 510a-510 f may be configured to receive two or more of the NGBT servicesfrom one or more of the broadcast providers.

The receivers 510 a-510 f receive the plurality of NGBT services from atleast two broadcast providers. In another embodiment, the receivers 510a-510 f receive the plurality of NGBT services from at least onebroadcast provider. The receivers 510 a-510 f provide the receivedplurality of NGBT services to a multiplexer 515 that generates abroadcast multiplex including the plurality of NGBT services andforwards the broadcast multiplex to a signal generator 520. The signalgenerator 520 generates a broadcast signal with the plurality of NGBTservices and provides the broadcast signal to a transmitter 530 forbroadcast to the reception apparatus 20.

In one embodiment, the signal generator 520 is an OFDM-based signalgenerator as illustrated in FIG. 6. As illustrated in FIG. 6, an inputformatter 610 receives the plurality of NGBT services from the receivers510 a-510 f and multiplexer 515. The input formatter 610 formats the IPpackets and/or transport streams associated with the plurality ofreceived NGBT services into packets of the same length for forward errorcorrection (FEC). A coded modulator 620 modulates the signal and astructure 630 performs framing output and signaling. A waveformgenerator 640 subsequently performs an inverse Fast Fourier transform(FFT) to generate the OFDM-based signal.

In one embodiment, a controller 660 controls the operation of each ofthe input formatter 610, coded modulator 620, structure 630, andwaveform generator 640. Further, the controller 660 provides signalinginformation to the structure 630. The signaling information includes,for example, FFT size (e.g., 1024, 4096, 8192, 32768, etc.), framestructure (i.e., how much data is in the frame), FEC structure (e.g.,LDPC coding structure), modulation setting (e.g., 1024QAM, 256QAM), etc.The controller 660 may be a dedicated controller for the signalgenerator 520 or implemented by a controller of the reception apparatus20.

The partner broadcast provider 15 b and/or transition broadcast provider25 may utilize a distribution system that is similar to the distributionsystem 500 described above. However, the signal generator 520 and/ortransmitter 530 are appropriately modified in accordance with thetransmission scheme used to broadcast the plurality of legacy servicesin the case of the partner broadcast provider 15 b. For example, thesignal generator 520 is configured to generate an 8-VSB modulationsignal. Further, the signal generator 520 may be configured to compress,or otherwise reduce the bit rate of, the received plurality of legacyservices when needed to fit the plurality of NGBT services into thebroadcast channel.

With regard to the transition broadcast provider 25, in one embodimentat least one receiver in the distribution system of the transitionbroadcast provider 25 receives a plurality of NGBT services from one ormore different broadcast providers. The plurality of NGBT services areprovided to the transition broadcast provider 25 via any one or acombination of communication means such as microwave transmissions(e.g., satellite or terrestrial), the Internet, a dedicated wiredconnection, cable television, shipping storage media containing thefirst service, etc. Similar communication means may also be utilized bythe partner broadcast providers 15 a, 15 b. A broadcast signal includingthe plurality of NGBT services is generated by a signal generator in thedistribution system and a transmitter broadcasts the plurality of NGBTservices over a transition broadcast channel.

FIG. 7 illustrates an exemplary protocol stack for a NGBT service. Inone embodiment, the physical layer is implemented using OFDM and LDPCcode. However, other encoding and/or error correction modes may beutilized. Applications of the protocol stack include a videopresentation, a social media interface, interactivity, ATSC 2.0, etc.For example, in one embodiment, the protocol stack provides a socialmedia interface to share content on Facebook that is being watched onthe reception apparatus 20. Broadcast content is sent via the userdatagram protocol (UDP), which sends data one-way (no hand-shaking), andthe social media interface is provided through the transmission controlprotocol (TCP) for hand-shaking acknowledgement of sent data, forexample using Moving Picture Experts Group (MPEG) Dynamic AdaptiveStreaming over Hypertext Transfer Protocol (DASH). MPEG DASH allows fordynamic control of service (video and audio) bit rate, which allows asmooth video to be maintained when networks are congested.

As illustrated in FIG. 7, the protocol stack includes a file deliveryunidirectional transport (FLUTE) as defined in RFC 392 for deliveringfiles in a transport, which is incorporated herein by reference in itsentirety. The protocol stack further includes short-term key messages(STKMs) and long-term key messages (LTKMs) used as keys for encryptedcontent, the real-time transport protocol (RTP) which provides real-timetransport of data, the real-time transport control protocol (RTCP) whichprovides out-of-band statistics and control information for an RTP flow,asynchronous layered coding (ALC) which allows fro asynchronous stuffingof data into a datagram (e.g., UDP), high efficiency video coding (HEVC)for video and/or audio coding. The hypertext transfer protocol (HTTP) isused mainly in Internet access; the ATSC 2.0/Service Guides are tablelistings of content; captioning/subtitling are text fragments describingvideo content; and media codecs are HEVC, object-oriented audio coding,etc. to be used in either broadcast or broadband connections.Application is the presentation of data to the display device.

FIG. 8 illustrates an embodiment of the reception apparatus 20. Thereception apparatus 20 is, or is integrated or an add-on component to, amobile device such as a cellular phone, tablet, smart phone, portablecomputer, etc. In other embodiments, the reception apparatus 20 is afixed device such as a digital television receiver device that isincorporated into a television set, a set top box, or any other fixeddevice configured to receive television content.

The reception apparatus 20 includes a tuner 802, which is configured totune to different broadcast channels and receive one or a combination ofthe plurality of NGBT services broadcast by the partner broadcastprovider 15 a and the plurality of legacy services broadcast by thepartner broadcast provider 15 b and legacy broadcast provider 10 via aterrestrial broadcast.

It should be noted that in certain embodiments, the transmission oflegacy services by the partner broadcast provider 15 b and the legacybroadcast provider 10 is the same except that legacy services fromdifferent broadcast providers are transmitted by the partner broadcastprovider 15 b. For example, the legacy services utilize one or acombination of the same coding, bit rate, etc.

In one embodiment, the tuner 802 provides a broadcast signal receivedover a currently tuned broadcast channel to a receiver 806. The receiver806 extracts audio and video (A/V) streams from a selected one of theplurality of NGBT or legacy services. In one embodiment, the receiver806 is one or a combination of an 8-VSB and OFDM-based receiver.However, the receiver 806 may be configured to process other signaltypes such as an NGBT signal or other broadcast signal of a typedifferent from the signal broadcast by the broadcast providers 15 a, 15b. The audio is decoded by an audio decoder 810 and the video is decodedby a video decoder 814. Further, uncompressed A/V data may be receivedvia an uncompressed A/V interface (e.g., a HDMI interface). In oneembodiment, the uncompressed A/V interface is only provided when thereception apparatus 20 is a fixed device.

The broadcast signal includes supplemental data such as one or acombination of closed caption data, EPG data, interactive content, ATSC2.0 content, software applications, a social media interface, emergencyservices, accessibility data, etc. The supplemental data are separatedout by the receiver 806. However, the supplemental data may be receivedvia the Internet 30 and a network interface 226. The network interface226 includes one or a combination of wired and wireless interfaces(e.g., a Ethernet interface, cellular data network interface, etc.) Astorage memory 830 is provided to store non-real time orInternet-delivered content such as the supplemental data.

The reception apparatus 20 generally operates under control of at leastone processor, such as CPU 838, which is coupled to a working memory840, program memory 842, and a graphics subsystem 844 via one or morebuses (e.g., bus 850). The CPU 838 receives closed caption data from thereceiver 806 as well as any other supplemental data used for renderinggraphics, and passes appropriate instructions and data to the graphicssubsystem 844. The graphics outputted by the graphics subsystem 844 arecombined with video images by the compositor and video interface 860 toproduce an output suitable for display on a video display.

Further, the CPU 838 operates to carry out functions of the receptionapparatus 20 including the processing of the supplemental data (e.g.,interactivity, social media interfacing, etc.) and based on user inputsreceived from an input interface 852.

Although not illustrated in FIG. 8, the CPU 838 may be coupled to anyone or a combination of the reception apparatus 20 resources tocentralize control of one or more functions. In one embodiment, the CPU838 also operates to oversee control of the reception apparatus 20including the tuner 802 and other television resources.

FIG. 9 is a flow diagram of an exemplary reception method. In step S902,the reception apparatus 20 receives, via an input interface (e.g., atouch screen, remote control receiver, etc.) a selection of one of aplurality of NGBT services broadcast via a first broadcast channel. Instep S904, the reception apparatus 20 tunes to the first broadcastchannel.

In step S906, the reception apparatus 20 decodes the selected one of theplurality of NGBT services on the tuned first broadcast channel. Theplurality of NGBT services correspond to a plurality of legacy servicesbroadcast via a second broadcast channel. In certain embodiments, theplurality of NGBT services correspond to the plurality of legacyservices in that both contain different versions of the same content.For example, the plurality of first services include UHDTV versions, andthe plurality of second services include HDTV versions, of the sametelevision program

In step S908, the reception apparatus 20 outputs the selected one of theplurality of NGBT services on the first broadcast channel for display.

FIG. 10 is a block diagram showing an example of a hardwareconfiguration of a computer 1000 that can be configured to function as,control, or incorporate, any one or a combination of a distributionsystem for the partner broadcast providers 15 a, 15 b; receptionapparatus 20; server 40; and transition broadcast server 25.

As illustrated in FIG. 10, the computer 1000 includes a centralprocessing unit (CPU) 1002, read only memory (ROM) 1004, and a randomaccess memory (RAM) 1006 interconnected to each other via one or morebuses 1008. The one or more buses 1008 are further connected with aninput-output interface 1010. The input-output interface 1010 isconnected with an input portion 1010 formed by a keyboard, a mouse, amicrophone, remote controller, etc. The input-output interface 1010 isalso connected to an output portion 1014 formed by an audio interface,video interface, display, speaker, etc.; a recording portion 1016 formedby a hard disk, a non-volatile memory, etc.; a communication portion1018 formed by a network interface, modem, USB interface, fire wireinterface, etc.; and a drive 1020 for driving removable media 1022 suchas a magnetic disk, an optical disk, a magneto-optical disk, asemiconductor memory, etc.

According to one embodiment, the CPU 1002 loads a program stored in therecording portion 1016 into the RAM 1006 via the input-output interface1010 and the bus 1008, and then executes a program configured to providethe functionality of the one or combination of the distribution systemfor the partner broadcast providers 15 a, 15 b; reception apparatus 20;server 40; and transition broadcast server 25.

Although embodiments of the present disclosure are discussed withrespect to transitioning services for terrestrial broadcast channels,more particularly television broadcast channels, the transition plansdescribed above apply equally to radio station broadcasts (e.g., whentransitioning to a new services that includes picture content),satellite broadcasts, and any other communication method in whichtransmission capacity is limited.

The various processes discussed above need not be processedchronologically and/or in the sequence depicted as flowcharts; the stepsmay also include those processed in parallel or individually (e.g., inparalleled or object-oriented fashion).

Also, the programs may be processed by a single computer or by aplurality of computers on a distributed basis. The programs may also betransferred to a remote computer or computers for execution.

Furthermore, in this specification, the term “system” means an aggregateof a plurality of component elements (apparatuses, modules (parts),etc.). All component elements may or may not be housed in a singleenclosure. Therefore, a plurality of apparatuses each housed in aseparate enclosure and connected via a network are considered a system,and a single apparatus formed by a plurality of modules housed in asingle enclosure are also regarded as a system.

Also, it should be understood that this technology when embodied is notlimited to the above-described embodiments and that variousmodifications, variations and alternatives may be made of thistechnology so far as they are within the spirit and scope thereof.

For example, this technology may be structured for cloud computingwhereby a single function is shared and processed in collaboration amonga plurality of apparatuses via a network.

Also, each of the steps explained in reference to the above-describedflowcharts may be executed not only by a single apparatus but also by aplurality of apparatuses in a shared manner.

Furthermore, if one step includes a plurality of processes, theseprocesses included in the step may be performed not only by a singleapparatus but also by a plurality of apparatuses in a shared manner.

Numerous modifications and variations of the present disclosure arepossible in light of the above teachings. It is therefore to beunderstood that within the scope of the appended claims, the presentdisclosure may be practiced otherwise than as specifically describedherein.

The above disclosure also encompasses the embodiments noted below.

(1) A method for broadcasting a plurality of non-backwards-compatibleservices, the method comprising receiving, by a first service provider,a plurality of first services, including a first service associated withthe first service provider and a first service associated with a secondservice provider; generating a first broadcast multiplex including theplurality of first services, broadcasting, by the first serviceprovider, the first broadcast multiplex on a first broadcast channelallocated to the first service provider; receiving, by the secondservice provider, a plurality of second services, including a secondservice associated with the first service provider and a second serviceassociated with the second service provider; generating a secondbroadcast multiplex including the plurality of second services; andbroadcasting, by the second service provider, the second broadcastmultiplex on a second broadcast channel allocated to the second serviceprovider.

(2) The method according to feature (1), in which the plurality ofsecond services has a lower video resolution than the plurality of firstservices.

(3) The method according to feature (1) or (2), in which the pluralityof first services are encoded using a first coding and the plurality ofsecond services are encoded using a second coding, the first codingbeing different from the second coding.

(4) The method according to feature (3), in which the first coding isMPEG-2 or MPEG-4.

(5) The method according to any of features (1) to (4), in which theplurality of first and second services include television programs, andthe step of broadcasting the first broadcast multiplex includesbroadcasting at least one television program that is the same as atelevision program broadcast in the step of broadcasting the secondbroadcast multiplex.

(6) The method according to any of features (1) to (5), in which atleast two of the plurality of second services are broadcast on the samephysical broadcast channel and assigned different major virtual channelnumbers.

(7) The method according to any of features (1) to (6), in which thefirst and second service providers are digital television broadcastproviders, the second service provider broadcasts digital televisioncontent over the second broadcast channel using an 8-level vestigialsideband modulation (8-VSB) modulation method, and the first serviceprovider broadcasts digital television content using a modulation methoddifferent from the 8-VSB modulation method.

(8) The method according to any of features (1) to (7), furthercomprising entering into a contract between the first and second serviceproviders to provide the plurality of first services on the firstbroadcast channel and the plurality of seconds services on the secondbroadcast channel.

(9) A distribution system, comprising a first service provider,including

a first receiver configured to receive a plurality of first services,including a first service associated with the first service provider anda first service associated with a second service provider, a firstmultiplexer configured to generate a first broadcast multiplex includingthe plurality of first services, and a transmitter configured tobroadcast the first broadcast multiplex on a first broadcast channelallocated to the first service provider; and the second serviceprovider, including a second receiver configured to receive a pluralityof second services, including a second service associated with the firstservice provider and a second service associated with the second serviceprovider; a second multiplexer configured to generate a second broadcastmultiplex including the plurality of second services, and a secondtransmitter configured to broadcast the second broadcast multiplex on asecond broadcast channel allocated to the second service provider.

(10) The distribution system according to feature (9), in which theplurality of second services have a lower video resolution than theplurality of first services.

(11) The distribution system according to feature (9) or (10), in whichthe plurality of first services are encoded using a first coding and theplurality of second services are encoded using a second coding, thefirst coding being different from the second coding.

(12) The distribution system according to feature (11), in which thefirst coding is MPEG-2 or MPEG-4.

(13) The distribution system according to any of features (9) to (12),in which the plurality of first and second services include televisionprograms, and the first transmitter broadcasts at least one televisionprogram that is the same as a television program broadcast by the secondtransmitter.

(14) The distribution system according to any of features (9) to (13),in which at least two of the plurality of second services are broadcaston the same physical broadcast channel and assigned different majorvirtual channel numbers.

(15) The distribution system according to any of features (9) to (14),in which the first and second service providers are digital televisionbroadcast providers, the second service provider broadcasts digitaltelevision content over the second broadcast channel using an 8-levelvestigial sideband modulation (8-VSB) modulation method, and the firstservice provider broadcasts digital television content using amodulation method different from the 8-VSB modulation method.

(16) The distribution system according to any of features (9) to (15),in which the first and second service providers have a contract toprovide the plurality of first services on the first broadcast channeland the plurality of second services on the second broadcast channel.

(17) A reception apparatus configured to receive a plurality of firstservices from a plurality of different broadcast providers on a firstbroadcast channel, the reception apparatus comprising circuitryconfigured to receive a selection of one of the plurality of firstservices broadcast via the first broadcast channel, to tune to the firstbroadcast channel, to decode the selected one of the plurality of firstservices on the tuned first broadcast channel, the plurality of firstservices corresponding to a plurality of second services from theplurality of different broadcast providers broadcast on a secondbroadcast channel, and to output the selected one of the plurality offirst services on the transition broadcast channel for display.

(18) The reception apparatus according to feature (17), in which atleast two of the plurality of services are associated with differentmajor virtual channel numbers.

1. A reception apparatus, comprising: circuitry configured to receive aselection of one of a plurality of first services from a plurality ofdifferent broadcast providers, the plurality of first services from theplurality of different broadcast providers being broadcast on a firstsingle wireless radio frequency (RF) broadcast channel allocated to afirst broadcast provider of the plurality of different broadcastproviders, tune to the first single wireless RF broadcast channelallocated to the first broadcast provider, receive at least two of theplurality of first services being originally broadcast on the firstsingle wireless RF broadcast channel allocated to the first broadcastprovider, each of the at least two of the plurality of first servicesbeing identified by a first major virtual channel number identifying thefirst service provider and a different minor virtual channel number,decode the selected one of the plurality of first services broadcast onthe tuned first single wireless RF broadcast channel, and output theselected one of the plurality of first services for display, wherein theselected one of the plurality of first services is identified by asecond major virtual channel number identifying a second servicebroadcast provider of the plurality of different broadcast providers anda second minor virtual channel number, and wherein the first majorvirtual channel number is different from the second major virtualchannel number, and wherein the circuitry is configured to receive asecond service, which is a same service as one of the plurality of firstservices but with a different format, from a wireless RF broadcastchannel different from the single wireless RF broadcast channel.
 2. Thereception apparatus according to claim 1, wherein two or more of theplurality of first services, from the plurality of different broadcastproviders and broadcast on the first single wireless RF broadcastchannel, are associated with different major virtual channel numbers. 3.The reception apparatus according to claim 1, wherein the plurality offirst services broadcast on the first single wireless RF broadcastchannel includes first services of the first and second broadcastproviders; and a plurality of second services broadcast on a secondsingle wireless RF broadcast channel allocated to the second broadcastprovider includes second services of the first and second broadcastproviders.
 4. The reception apparatus according to claim 1, wherein thesecond service is assigned a combination of major and minor virtualchannel numbers different from a combination of major and minor virtualchannel numbers assigned to the one of the first services, whichprovides the same service as the second service but with a differentformat.
 5. The reception apparatus according to claim 1, wherein thecircuitry is configured to tune to a second single wireless RF broadcastchannel, and decode a selected one of a plurality of second services onthe tuned second single wireless RF broadcast channel, and the pluralityof first services are transmitted according to a first modulation schemeand the plurality of second services are transmitted according to asecond modulation scheme, the first and second modulation schemes beingdifferent.
 6. A method for receiving a plurality of first services froma plurality of different broadcast providers on a first single wirelessradio frequency (RF) broadcast channel, the method comprising:receiving, by circuitry of a reception apparatus, a selection of one ofthe plurality of first services from the plurality of differentbroadcast providers, the plurality of first services from the pluralityof different broadcast providers being broadcast on the first singlewireless RF broadcast channel allocated to a first broadcast provider ofthe plurality of different broadcast providers, tuning, by thecircuitry, to the first single wireless RF broadcast channel allocatedto the first broadcast provider, receiving at least two of the pluralityof first services being originally broadcast on the first singlewireless RF broadcast channel allocated to the first broadcast provider,each of the at least two of the plurality of first services beingidentified by a first major virtual channel number identifying the firstservice provider and a different minor virtual channel number, decoding,by the circuitry, the selected one of the plurality of first servicesbroadcast on the tuned first single wireless RF broadcast channel, andoutputting the selected one of the plurality of first services fordisplay, wherein the selected one of the plurality of first services isidentified by a second major virtual channel number identifying a secondservice broadcast provider of the plurality of different broadcastproviders and a second minor virtual channel number, and wherein thefirst major virtual channel number is different from the second majorvirtual channel number, and wherein the method further comprisesreceiving a second service, which is a same service as one of theplurality of first services but with a different format, from a wirelessRF broadcast channel different from the single wireless RF broadcastchannel.
 7. The method according to claim 6, wherein two or more of theplurality of first services, from the plurality of different broadcastproviders and broadcast on the first single wireless RF broadcastchannel, are associated with different major virtual channel numbers. 8.The method according to claim 6, wherein the plurality of first servicesbroadcast on the first single wireless RF broadcast channel includesfirst services of the first and second broadcast providers; and aplurality of second services broadcast on a second single wireless RFbroadcast channel includes second services of the first and secondbroadcast providers.
 9. The method according to claim 6, furthercomprising: tuning to a second single wireless RF broadcast channel, anddecoding a selected one of a plurality of second services on the tunedsecond single wireless RF broadcast channel, wherein the plurality offirst services are transmitted according to a first modulation schemeand the plurality of second services are transmitted according to asecond modulation scheme, the first and second modulation schemes beingdifferent.
 10. A non-transitory computer-readable medium storinginstructions which when executed by a computer cause the computer toperform a method for receiving a plurality of first services from aplurality of different broadcast providers on a first single wirelessradio frequency (RF) broadcast channel, the method comprising:receiving, by the computer, a selection of one of the plurality of firstservices from the plurality of different broadcast providers, theplurality of first services from the plurality of different broadcastproviders being broadcast on the first single wireless RF broadcastchannel allocated to a first broadcast provider of the plurality ofdifferent broadcast providers, tuning, by the computer, to the firstsingle wireless RF broadcast channel allocated to the first broadcastprovider, receiving at least two of the plurality of first servicesbeing originally broadcast on the first single wireless RF broadcastchannel allocated to the first broadcast provider, each of the at leasttwo of the plurality of first services being identified by a first majorvirtual channel number identifying the first service provider and adifferent minor virtual channel number, decoding, by the computer, theselected one of the plurality of first services broadcast on the tunedfirst single wireless RF broadcast channel, and outputting the selectedone of the plurality of first services for display, wherein the selectedone of the plurality of first services is identified by a second majorvirtual channel number identifying a second service broadcast providerof the plurality of different broadcast providers and a second minorvirtual channel number, and wherein the first major virtual channelnumber is different from the second major virtual channel number. 11.The non-transitory computer-readable medium according to claim 10,wherein two or more of the plurality of first services, from theplurality of different broadcast providers and broadcast on the firstsingle wireless RF broadcast channel, are associated with differentmajor virtual channel numbers.
 12. The non-transitory computer-readablemedium according to claim 10, wherein the plurality of first servicesbroadcast on the first single wireless RF broadcast channel includesfirst services of the first and second broadcast providers; and aplurality of second services broadcast on a second single wireless RFbroadcast channel allocated to the second broadcast provider includessecond services of the first and second broadcast providers.
 13. Thenon-transitory computer-readable medium according to claim 10, furthercomprising: tuning to a second single wireless RF broadcast channel, anddecoding a selected one of a plurality of second services on the tunedsecond single wireless RF broadcast channel, wherein the plurality offirst services are transmitted according to a first modulation schemeand the plurality of second services are transmitted according to asecond modulation scheme, the first and second modulation schemes beingdifferent.
 14. A transmitter comprising: circuitry configured totransmit a plurality of first services from a plurality of differentbroadcast providers, the plurality of first services from the pluralityof different broadcast providers being broadcast on a first singlewireless radio frequency (RF) broadcast channel allocated to a firstbroadcast provider of the plurality of different broadcast providers,wherein at least two of the plurality of first services being originallybroadcast on the first single wireless RF broadcast channel allocated tothe first broadcast provider, each of the at least two of the pluralityof first services being identified by a first major virtual channelnumber identifying the first service provider and a different minorvirtual channel number, one of the plurality of first services isidentified by a second major virtual channel number identifies a secondservice broadcast provider of the plurality of different broadcastproviders and a second minor virtual channel number, and the first majorvirtual channel number is different from the second major virtualchannel number, and transmit a second service, which is a same serviceas one of the plurality of first services but with a different format,via a wireless RF broadcast channel different from the single wirelessRF broadcast channel.
 15. The transmitter according to claim 14, whereintwo or more of the plurality of first services, from the plurality ofdifferent broadcast providers and broadcast on the first single wirelessRF broadcast channel, are associated with different major virtualchannel numbers.
 16. The transmitter according to claim 14, wherein theplurality of first services broadcast on the first single wireless RFbroadcast channel includes first services of the first and secondbroadcast providers; and the circuitry is configured to transmit aplurality of second services via a second single wireless RF broadcastchannel allocated to the second broadcast provider, the plurality ofsecond services includes second services of the first and secondbroadcast providers.
 17. The transmitter according to claim 16, whereinthe plurality of first services are transmitted according to a firstmodulation scheme and the plurality of second services are transmittedaccording to a second modulation scheme, the first and second modulationschemes being different.
 18. The transmitter according to claim 14, thesecond service is assigned a different combination of major and minorvirtual channel numbers than a combination of major and minor virtualchannel numbers assigned to the one of the first services, whichprovides the same service as the second service but with a differentformat.
 19. A transmission method comprising: transmitting a pluralityof first services from a plurality of different broadcast providers, theplurality of first services from the plurality of different broadcastproviders being broadcast on a first single wireless radio frequency(RF) broadcast channel allocated to a first broadcast provider of theplurality of different broadcast providers, wherein at least two of theplurality of first services being originally broadcast on the firstsingle wireless RF broadcast channel allocated to the first broadcastprovider, each of the at least two of the plurality of first servicesbeing identified by a first major virtual channel number identifying thefirst service provider and a different minor virtual channel number, oneof the plurality of first services is identified by a second majorvirtual channel number identifies a second service broadcast provider ofthe plurality of different broadcast providers and a second minorvirtual channel number, and the first major virtual channel number isdifferent from the second major virtual channel number, and transmit asecond service, which is a same service as one of the plurality of firstservices but with a different format, via a wireless RF broadcastchannel different from the single wireless RF broadcast channel.
 20. Thetransmission method according to claim 19, wherein the second service isassigned a different combination of major and minor virtual channelnumbers than a combination of major and minor virtual channel numbersassigned to the one of the first services, which provides the sameservice as the second service but with a different format.